It doesn’t take long for spider mites to attack tomatoes and attack with a passion as the weather gets hotter. I usually get a lot of calls this time of year about tomatoes that are turning yellow, and, in most cases, it is spider mites that are the culprit.
Notice the dark spots on either side, hence the name.
The two spotted spider mite is responsible for a lot of our tomato problems. They are very small at 1/32 of an inch or less. If you turn over a tomato leaf you will see the webbing characteristic of spider mites and if you look closer, you may see the actual mite moving around. Spider mites overwinter as adults and even continue to breed on host plants in mild winters. Spider mite adults lay a clear to yellow egg suspended in a fine web of silk. 6-legged nymphs emerge from the eggs and go through 2 molts before they emerge as 8-legged adults. A generation can last from 5 to 20 days depending on the temperature, the hotter the quicker. When the host plant begins to decline, the mites spin silk threads and use these strands to “fly” or “balloon” in wind to disperse to other plants. This is how they get to your tomatoes in the first place. Under ideal conditions (hot, dry weather, lack of natural enemies, and well-fertilized plants), mite populations can increase 10-fold per week!
Spider mites on a tomato stake about to spin a silk thread and take off!
Scouting is essential to control. If you see spider mites early you can wash them off with hard streams of water or use an insecticidal soap. Sulphur has long been used as a preventative for mites as well as a fungicide for diseases. Garlic and other botanicals have been promoted, but my experience has not been good. Organic products that have a good track record are Certis Biologicals – BoteGHA, PFR-97, Sil-Matrix, DES-X and Trilogy. Pro Farm – Grandevo and Venerate. Spinosad made by several companies can be effective. There are a whole host of botanical oils from garlic to thyme to peppermint and can be a preventative or good in light infestations. Another option is beneficial insect releases like Phytoseiulus persimilis or Neoseiulus cucumeris beneficial mites which are known to be very effective.
Severe spider mite infestation – pull out the plant!
Unfortunately, most gardeners do not notice infestations until they are severe, and control by then is difficult. I like to recommend that gardeners remove the plants that are somewhat infested. This may seem drastic but letting populations explode doesn’t seem healthy either.
Lastly let me add that spider mites love plants that are stressed, especially from water. I was recently running a greenhouse experiment with tomatoes and marigolds. I had many pots of each, and I had inadvertently left some of both plants almost outside the area that was sprinkler watered. This meant that 2 tomato plants and 2 marigold plants were getting just enough water to live but not much else. I then went on vacation for a few days and when I came back the only spider mite infested plants were those stressed for water. I have seen this in fields over and over again, water stress brings on insect stress! Tomato plants can use 1.5 gallons of water every day and most gardeners only water once a week.
Properly managing stored grain is essential to maintaining its quality and preventing insect infestations. Below are some strategies for controlling insects in organic grain storage, focusing on beneficial insects, biological sprays, and preventive measures. Just a reminder always, always check with your certifier about using these practices in your OSP and before making grain applications!
Clean Storage Areas: Thoroughly clean and disinfect storage areas before storing new grain. Remove any residual grain, debris, and dust, as these can harbor pests.
Proper Drying: Ensure that grain is properly dried to a moisture content below 14%. High moisture levels can promote mold growth and attract insects.
Sealed Containers: Store grain in airtight containers or silos to prevent insect entry. Use insect-proof storage bags or bins for smaller quantities.
Regular Monitoring: Inspect stored grain regularly for signs of infestation. Use pheromone traps to monitor pest activity and take action if necessary.
Temperature Control: Keep storage areas cool, as high temperatures can encourage insect activity. Aerate grain periodically to maintain uniform temperature and moisture levels.
Predator Insects for Grain Storage
Predatory insects are an innovative and sustainable solution for managing pests in stored grain. These beneficial insects naturally prey on grain pests, helping to keep their populations in check without the need for chemical treatments. To implement the use of predatory insects, it’s crucial to monitor pest populations and introduce the predators at the right time. Maintaining optimal storage conditions, such as proper temperature and humidity, will also enhance the effectiveness of these biological controls.
Predatory Mites (Acarina: Phytoseiidae): These mites’ prey on grain mites and small insect pests, effectively reducing pest populations in stored grain.
Parasitoid Wasps (e.g., Trichogramma spp.): These wasps lay their eggs inside the eggs of pest insects like moths and beetles. The developing wasp larvae consume the pest eggs, preventing the pests from emerging.
Lesser Grain Borer Parasitoids (e.g., Anisopteromalus calandrae): These wasps target larvae of grain borers and weevils, helping to reduce their numbers.
Diatomaceous Earth (DE): DE is a natural powder made from fossilized remains of diatoms. It works by damaging the exoskeletons of insects, causing them to dehydrate and die. It’s a safe and effective method for organic grain storage. Apply DE to the grain before storage to create a protective layer.
General Application: Use DE at a rate of approximately 1-2 pounds per ton of grain. Surface Treatment: For treating the surface of stored grain, apply a layer of DE at about 0.5 to 1 pound per 1,000 square feet.
How to Apply DE: Ensure the grain is clean and dry before applying DE. The moisture content should be below 14%, as DE is more effective in dry conditions.
Mixing with Grain: Add DE to the grain as it is being transferred into the storage bin. This can be done using a grain auger or conveyor belt. The movement will help mix DE uniformly throughout the grain.
Top Dressing: After filling the storage bin, apply DE on the top surface of the grain. This creates a barrier to prevent insects from entering the grain mass. For best results, ensure even distribution. DE should be mixed thoroughly with the grain to cover all kernels. Use personal protective equipment (PPE) such as a dust mask and gloves to avoid inhaling DE dust during application. A hand spreader or scoop can be used for smaller quantities, while larger operations may require mechanized equipment for even distribution.
Benefits of Using DE: DE is a natural, non-toxic substance safe for humans and animals. It leaves no harmful residues, making it suitable for organic storage systems. DE is effective against a wide range of insects, including weevils, beetles, and moths.
Additional Tips for DE: Maintain optimal storage conditions. DE is most effective in dry environments, so keeping grain dry and well-ventilated will enhance its efficacy. In long-term storage situations, periodically check the grain and reapply DE if needed, especially if there is significant handling or movement of grain. Always handle DE with care to avoid inhalation and ensure it does not contact eyes. Use in a well-ventilated area or wear appropriate protective gear.
Neem Oil (Azadirachtin): Extracted from the neem tree, neem oil has insecticidal properties that disrupt the life cycle of insects by interfering with their growth and reproduction. It can be used as a spray in storage areas or directly on grain. Here are some products:
Azadirachtin 1.2%
Aza-Direct, AzaPro
Azadirachtin 3%
AzaGuard, Molt-X
Azadirachtin 4.5%
Neemix 4.5
Azadirachtin: 6.0%
Azasol
Bacillus thuringiensis (Bt): Bt is a soil-dwelling bacterium that produces proteins toxic to certain insects. When ingested by insects, Bt causes them to stop feeding and eventually die. Bt formulations can be sprayed on grain to control pests like moths and beetles. Here are some products:
Bacillus thuringiensis aizawai
Agree, Xentari
Certis, Valent
bacteria
Bacillus thuringiensis israelensis
Gnatrol, AquaBac
Valent, Becker Microbial
bacteria
Bacillus thuringiensis kurstaki
DiPel, Deliver, Javelin, BT Now, Leprotec
NuFarm, Valent, Certis, BioSafe, Vestaron
bacteria
Using Pheromone Traps for Organic Grain Storage Pest Control
Pheromone traps are an effective tool for monitoring and controlling insect pests in organic grain storage. They work by emitting synthetic versions of insect pheromones, which attract pests to the trap, thereby reducing their populations and minimizing damage to stored grain.
Benefits of Pheromone Traps
1. Target Specific Pests: Pheromone traps are designed to attract specific insect species, making them effective in targeting particular pests without affecting non-target organisms.
2. Monitoring Pest Activity: These traps help farmers monitor pest populations and detect early infestations, allowing for timely intervention.
3. Reducing Chemical Use: By using pheromone traps, farmers can reduce or eliminate the need for chemical insecticides, aligning with organic farming principles.
Types of Pheromone Traps
1. Sticky Traps: These traps are coated with a sticky substance that captures insects when they land on them. They are commonly used for moths and beetles.
2. Delta Traps: Reusable plastic traps that are suitable for a variety of pests. They are durable and weather-resistant, making them ideal for outdoor use.
3. Wing Traps: These traps are weather-resistant and feature a grid pattern on the bottom for easy counting of trapped insects. They are effective in orchards and greenhouses.
How to Use Pheromone Traps
1. Placement: Position traps at the top and in the center of the grain mass. Pheromone traps can also be placed around the storage area to monitor incoming pests.
2. Monitoring: Check the traps regularly to monitor pest activity. Replace the pheromone lures as needed, typically every 4-6 weeks.
3. Maintenance: Keep traps clean and ensure they are in good condition to maintain their effectiveness.
The organic label is more than just a marketing term; it is a rigorous standard of quality that reflects sustainable and environmentally friendly practices across the agricultural sector. The USDA’s National Organic Program (NOP) is at the heart of this movement, ensuring that products labeled as organic meet stringent, federally regulated guidelines. This unified regulatory framework is crucial not just for maintaining the integrity of the organic label but also for investing in and supporting a diverse array of stakeholders involved in the organic supply chain—from farmers and researchers to retailers and consumers. Tools such as the USDA Organic Consumer Outreach Toolkit play a vital role in promoting these standards, ensuring that the value of organic products is clearly communicated and understood by the consumer but also by those outside looking in and examining the organic program family!
The Unified Regulatory Framework of Organic Agriculture
Organic agriculture operates under a comprehensive framework established by the NOP, which enforces consistency across the entire supply chain. This uniformity ensures that whether one is dealing with an organic dairy farm in Texas or a producer of organic vegetables in California, or a feed manufacturer in Illinois, all parties are held to the same high standards. This regulation not only supports the integrity of organic products but also helps streamline processes for stakeholders at all levels, including brokers, wholesalers, manufacturers, and retailers. The ability to trust in the label “organic” comes from this rigorous oversight and the commitment to upholding these standards universally.
Collaborative Efforts Across Stakeholders
One of the most remarkable aspects of the NOP’s structure is its collaborative nature, which fosters engagement across a broad spectrum of stakeholders. This collaboration includes:
Educational institutions and specialists: As an organic specialist with a land grant university, my role involves educating and guiding future and current farmers on best organic practices. Even specialists without organic in their title like agronomists, entomologists or plant pathologists contribute to organic knowledge and expertise. More and more these folks are finding ways to work with our natural plant and animal systems advancing organic agriculture.
University researchers are doing tremendous work and through their efforts organic ag is advancing faster and faster. I know, because of the many current organic grant projects just in Texas. Other research bodies, both public and private research, also are a part of this huge collaboration to advance organic agriculture from the farm all the way to the table.
Organizations and associations like the Organic Trade Association (OTA), The Organic Center (TOC), Organic Farm Research Foundation (OFRF) and many other non-profits work tirelessly to promote organic production practices and products, help foster collaborations, and advocate within the halls of government.
Certification entities and even certification inspectors all work together with growers and handlers to ensure that the system is protected from simple mistakes to outright fraud protecting a consumer based and backed program. They are not doing this just for themselves but for the grower and handler who needs the consumer to buy their products because they are certified organic.
Education and Outreach: Tools for Sustaining Organic Integrity
The USDA Organic Consumer Outreach Toolkit exemplifies the educational tools that are crucial for sustaining the integrity of the organic label. This toolkit is designed to educate stakeholders along the supply chain and inform consumers about what the organic label represents. Clear, consistent messaging helps to ensure that the organic label retains its value and significance in the marketplace. For instance, retail employees can use the toolkit to better explain the benefits of organic products to customers, reinforcing trust and understanding.
I will admit this is a tough one! We do not have the support systems and advisory services we need within the organic community. Extension organic specialists and county extension agents and even private advisors and consultants to provide ongoing support and guidance, have been in short supply – but it is improving. This continual knowledge exchange is vital for keeping up with the fast-changing organic systems research, the new and innovative products for organic production, the regulatory environment we work within and of course, any and all emerging trends in organic agriculture.
Traceability and Transparency: Building Consumer Trust
A cornerstone of the NOP’s approach is the emphasis on traceability and transparency. From farm to retail store, every step of the organic product’s journey is documented (and includes a certified entity), ensuring that the products consumers buy are genuinely organic. This traceability not only helps in enforcing compliance with organic standards but also builds consumer confidence in the organic label. According to a recent consumer survey conducted by the Organic Trade Association 88% of all consumers know about the organic label and are willing to pay more because of their trust in the label.
Conclusion
The USDA National Organic Program’s structured approach to regulating and promoting organic agriculture underpins the integrity and trust in the organic label. By fostering a unified and collaborative framework, the NOP ensures that organic standards are not just ideals but practical realities that benefit the environment, producers, and consumers alike. As we look to the future, your continued support and participation in this program will be crucial for advancing sustainable agricultural practices and increasing organic farming, manufacturing, retailing and consumption. How? By realizing you are part of an “organic family” that promotes you and your business along with every other part of the value chain (traceability means you get promoted) all the way to the consumer who picks up your product and knows you are part of that product.
I know that all these rules and regulations and the piles of paperwork get overwhelming but know that this helps the consumer to feel a part of your production and ultimately your farm. Here are a few examples or Case Studies of what things may look like in the future as we try to invite the consumer to be part of this value chain known as Organic Farming.
Some real-world examples of building consumer trust
Case Study 1: Carrefour and Blockchain
Overview: Carrefour, (big in Europe and the Middle East) a global retail giant, launched a blockchain-based traceability system for several products, including organic fruits and vegetables. The system allows consumers to scan a QR code on the product packaging to access detailed information about the production process.
Key Features:
Farm to Fork Information: Consumers can see details about where and how the organic produce was grown, including the farm’s location, the farming practices used, and the harvest date.
Transparency and Trust: By providing a clear view of the supply chain, Carrefour enhances consumer trust in their organic label.
Case Study 2: IBM Food Trust and Walmart
Overview: Walmart joined the IBM Food Trust, a blockchain-based system, to improve the traceability of its food products. The initiative initially focused on conventional products but has extended to organic products to ensure their integrity.
Key Features:
Enhanced Traceability: The system tracks every transaction from the supplier to the store, ensuring that organic standards are maintained at every step.
Rapid Response to Issues: If an issue arises, such as a contamination risk, Walmart can quickly trace the product back to its source and manage the situation effectively.
Case Study 3: Ripe.io and Tomato Traceability
Overview: Ripe.io uses blockchain technology to provide transparency in the tomato supply chain. Although not exclusively organic, the principles applied can directly benefit organic markets by detailing each step of a tomato’s journey from seed to supermarket.
Key Features:
Detailed Product Insights: Information on when and how tomatoes were planted, cared for, harvested, and transported are all recorded.
Consumer Feedback Integration: Consumers can provide feedback on the quality of the product, which can be used to improve farming practices.
On May 2, 2024, I had the privilege of attending and speaking at the Texas A&M AgriLife Research and Extension Center in Uvalde – Vegetable Spring Field Day. The field day featured a morning walking tour of all the research going on at the center and one of the stops was extremely interesting and informative especially since it covered an area of agriculture I had never heard about. Del Craig with Bridgestone Company (maker of many brands of tires) was on hand to talk about their continued research into a plant called “Guayule,” and it was a fascinating introduction!
Guayule is a shrub native to the southwestern United States and northern Mexico. The correct spelling is Parthenium argentatum, and it’s indeed a source of natural rubber. Guayule is particularly interesting because it offers an alternative to the traditional rubber source, the Hevea brasiliensis tree, which is grown primarily in Southeast Asia.
Characteristics of Guayule
Habitat: Guayule thrives in semi-arid climates, making it well-suited for regions where few other economic crops can grow.
Appearance: It’s a woody perennial that can reach up to 3 feet in height. It has a silver-gray appearance due to its hairy leaves, which help minimize water loss.
Rubber Production: Unlike the rubber tree, guayule produces rubber biopolymers in its bark and roots rather than in its sap. This rubber is harvested by grinding the whole plant and using a solvent-extraction process. Del Craig explained that the whole plant is harvested like you would harvest hay and then taken to processing.
Environmental and Economic Benefits
Sustainability: Since guayule grows in semi-arid regions, it requires less water than traditional rubber crops, making it an environmentally friendly alternative.
Hypoallergenic Properties: The rubber from guayule does not contain the proteins responsible for latex allergies, making it safe for use in medical supplies like gloves and catheters.
Economic Potential: It offers economic benefits for arid and semi-arid regions, providing a viable crop option that can support local economies without the extensive use of irrigation.
Research and Applications
Research is ongoing into optimizing the cultivation and processing of guayule for rubber extraction. This includes genetic breeding for traits such as increased rubber yield and disease resistance.
Current applications of guayule rubber include tires, medical products, and even consumer goods like footwear and adhesives.
The Uvalde Center has been a good test site but Del explained on the tour that they are also establishing a project in the Rio Grande Valley and at the Lubbock Research and Extension Center. These multiple sites allow for lots of experimentation on varieties in different eco-zones.
Could it grow in the South Plains?
In the pursuit for sustainable agricultural solutions in regions like the South Plains of Texas with limited water resources, guayule could be a great alternative to consider. Native to arid environments and native to Texas, this drought-resistant shrub is ideally suited to the South Plains of Texas, where traditional water-intensive crops struggle. Mr. Craig told me personally that they are looking into the possibility of the Plains to Brownfield to Seminole area being ideal for production.
One of the most compelling attributes of guayule is its water efficiency. This plant thrives in semi-arid climates, utilizing very deep root systems that tap into lower soil moisture levels and leaves adapted to minimize water loss. These features allow guayule to sustain itself and produce economically valuable rubber with minimal irrigation, aligning perfectly with the water conservation needs of the South Plains.
Moreover, guayule is adaptable to various soil types, increasing its viability across different landscapes within the region. Its introduction could diversify agricultural practices, reduce economic risks from crop failures, and provide farmers with a new revenue stream through the production of biodegradable rubber products.
The environmental benefits of cultivating guayule are also noteworthy. By stabilizing soil and reducing erosion on marginal lands, it enhances soil health and supports the local ecosystem. Del Craig also commented that they have looked at the carbon sequestration ability of the plant and its deep and extensive root system makes it a winner. To fully integrate guayule into the South Plains, initiatives such as pilot projects to tailor cultivation techniques, local agronomic support, and the establishment of processing facilities are essential.
“Twinning” or “doubles” in peaches refers to the phenomenon where a single peach flower bud develops into two closely connected fruits. This occurrence is often related to the conditions experienced by the tree during the bud initiation phase of the previous year. I have been thinning my peach trees and I am seeing a large number of doubles and yet I still have plenty of fruit – so far! Several factors can contribute to the development of doubles in peach trees, with stress playing a significant role. Let’s explore these factors in more detail:
Temperature Fluctuations: Extreme temperature variations, especially during the critical period of bud differentiation, can cause abnormalities in the developing fruit. If cold temperatures follow a period of warm weather that initiated early bud development, the stress can lead to the formation of doubles.
Water Stress: Both excessive water and drought conditions can stress the tree and disrupt the normal development of fruit buds. Proper water management is crucial during the growing season to prevent such stress. I think this was a big part of the issue because we had very little rain and also hot temperatures last year.
Nutritional Stress: An imbalance in essential nutrients, particularly during the bud initiation and development stages, can lead to the formation of doubles. High nitrogen levels, for example, can promote excessive vegetative growth at the expense of normal fruit development, potentially causing abnormalities.
Genetic Factors: Some peach varieties are more prone to producing doubles than others. This genetic predisposition can be exacerbated by environmental stresses.
Pesticide or Herbicide Exposure: Certain chemicals, if applied improperly or at sensitive stages of development, can cause physiological stress to the trees, leading to abnormalities in fruit development. 2,4-D, a common lawn and pasture weed killer, can also act as a plant hormone and cause deformities.
Addressing these stress factors can help reduce the incidence of doubles in peach production. Careful management of orchard conditions, including temperature control where possible, appropriate watering, balanced nutrition, and cautious use of chemicals, can improve the overall health of the trees and reduce the occurrence of doubles. Selecting varieties less prone to this issue can also be a strategic decision for orchard management.
Larry Stein, Ph.D., AgriLife Extension horticulturist and professor in the Texas A&M College of Agriculture and Life SciencesDepartment of Horticultural Sciences and located at the Uvalde center is a very good friend and mentor. He spoke about both chill hours and peach doubles in a recent AgriLife News article. He said, “chill hours have been sufficient in the mid-to-low chill areas, but were marginal in the higher chill areas, with a lot of growers reporting “doubles” on plant blooms.”
“Doubles or multiple fruit come about as the result of stress during the flower initiation stage, which would have been May and June of 2023,” he said. “These doubles seem to be the consensus when talking to area producers, with some saying they are getting three and four fruit from a single bloom.”
According to Dr. Stein, irregular or inadequate watering has also been identified as a likely cause of fruit splitting and doubling.
“Consumers usually consider conjoined fruits less visually appealing,” Stein said. “For producers, sometimes the extra piece of fruit is so small as to be insignificant and can be safely removed without harming the main fruit. To avoid the conjoined fruit, producers typically thin their fruit trees to get as many double or multiple fruits back to singles as possible.”
Typical tree fruit load before thinning! We must thin to a fruit every 4-6 inches.It’s hard to remove fruit especially since we don’t know what the weather will bring!
The global wine industry is witnessing a pivotal shift towards organic practices, a trend strongly reflected in the Lone Star State. Although Texas’s organic grape production is currently led by only 3 farmers cultivating over 200 acres, this growing segment is set to change the Texas wine landscape. This rise in organic viticulture, coupled with an increasing consumer interest in organic wines over the last decade, sets the stage for a deeper exploration of innovative solutions like Fungus Resistant Grape (FRG) varieties.
Why Organic? The Texas Perspective
In Texas, where the climate varies from the arid conditions of the High Plains to the humid Gulf Coast, viticulturists face a unique set of challenges. Disease pressure, particularly from fungal pathogens, is a significant concern that can compromise grape quality and yield. Herein lies the importance of FRG varieties, which offer hope for organic viticulture in Texas and similar environments. The adoption of these disease-resistant varieties can not only enhance the sustainability of vineyards but also align with the growing consumer demand for wines produced “environmentally friendly.” There is a tremendous amount of evidence that the organic label has a huge and growing recognition with consumers, and they are buying organic at an ever-increasing rate.
The Organic Wine Boom
Nationally and globally, the last decade has seen a marked increase in interest and sales of organic wines. Consumers are increasingly drawn to organic labels, not just for the perceived health benefits but also for their environmental impact. This shifting preference underscores the need for viticulture practices that prioritize ecological balance and sustainability. In Texas, where the wine industry is as dynamic as it is diverse, the integration of FRG varieties into organic viticulture holds the promise of meeting this demand while addressing the agronomic challenges of organic grape production.
Disease Resistance: A Game-Changer for Organic Viticulture
In past research FRG varieties such as Regent and many others have demonstrated remarkable resilience against fungal diseases that commonly afflict vineyards, reducing the reliance on fungicides and thus supporting organic farming principles (Pedneault and Provost, 2016). The most common Fungus-Resistant Grape (FRG) varieties grown and sold today include:
Regent
Regent: Developed in Germany, Regent is popular in cooler wine regions due to its resistance to both downy and powdery mildew. It produces red wines with deep color and robust flavors.
Marechal Foch: An early-ripening variety known for its resistance to several grape diseases, including downy mildew. It is used to make a range of wines from light reds to rich, full-bodied wines with dark fruit flavors.
Seyval Blanc: This variety is resistant to powdery mildew and is versatile in winemaking, used for producing everything from sparkling wines to well-balanced still whites.
Solaris: Bred in Sweden, Solaris is resistant to most fungal diseases and is suitable for organic viticulture. It produces aromatic white wines with high acidity and tropical fruit flavors.
Marquette: A cold-hardy variety developed by the University of Minnesota, Marquette is resistant to downy and powdery mildew and produces medium-bodied red wines with notes of cherry, blackberry, and spices.
Camminare Noir: developed by the University of California, Davis, as part of their breeding program for disease-resistant grapes, is a hybrid cross between a Vitis vinifera wine grape variety (94%) and American species known for their disease resistance. It is highly resistant to Pierces disease (PD), powdery mildew and downy mildew, making it particularly well-suited for regions where these fungal diseases are significant challenges.
Crimson Cabernet: developed by David and Ann Munson in Missouri, USA, is a hybrid of Norton (Vitis aestivalis, native to North America) and Cabernet Sauvignon. Bred specifically for cold climates, it offers excellent resistance to PD and to fungal diseases, including black rot and mildews. Norton contributes exceptional disease resistance and cold hardiness, while Cabernet Sauvignon imparts high wine quality and a recognizable flavor profile.
Paseante Noir: Produces wines similar to Pinot Noir, offering a light to medium body with delicate fruit flavors and good structure. It is resistant to Pierce’s Disease and moderately resistant to fungal diseases like powdery mildew. This variety is ideal for warmer regions with high PD pressure but performs well in less disease-prone areas too.
Errante Noir: Produces full-bodied red wines reminiscent of Syrah, with rich fruit flavors, good tannin structure, and aging potential. It combines strong resistance to Pierce’s Disease with moderate fungal resistance, making it an excellent option for growers in hot climates with heavy PD pressure.
Ambulo Blanc: White variety that resembles Sauvignon Blanc in its crisp acidity, citrus notes, and fresh aromatics. It offers high resistance to Pierce’s Disease and moderate fungal resistance, making it suitable for humid, warm regions where white grape production is challenging.
Caminante Blanc: Produces wines akin to Chardonnay, with balanced acidity and flavors of apple, pear, and subtle oak when barrel aged. It is highly resistant to Pierce’s Disease and moderately resistant to fungal pathogens, thriving in regions with significant PD pressure while supporting premium white wine production.
Regarding the use of FRG varieties in Texas, these varieties could translate to lower production costs, reduced environmental impact, and the potential for higher yields—key factors in the sustainability equation of organic viticulture. However, Texas’s diverse climate and the presence of various grape diseases make the state a potential area for adopting FRG varieties. The interest in sustainable and organic viticulture in Texas, along with the challenges posed by fungal diseases, suggest that FRG varieties could offer valuable solutions for Texan vineyards looking to reduce chemical inputs and manage disease more effectively.
Taste the Difference: The “Organoleptic” Advantage
Beyond the agronomic benefits, the organoleptic qualities (fancy word for a food or wine that stimulates our sense of taste or smell) of wines produced from FRG varieties offer a great argument for their adoption. Initial tastings and analyses reveal that these wines can compete with, if not exceed, the sensory profiles of wines made from traditional grape varieties (ones demanded now because they are considered superior). The promise of rich, complex flavors, coupled with the environmental benefits of organic viticulture, presents a compelling value proposition to consumers and wine “connoisseurs” alike. FRG varieties can change the industry for the better if allowed to by the very industry keeping them out!
Looking Ahead: Organic Viticulture in Texas
The growth of organic grape production in Texas, though in its early stages, is indicative of a broader trend towards sustainable viticulture practices. As the interest in organic wines continues to surge, the role of FRG varieties in enabling eco-friendly and economically viable grape production becomes increasingly significant. For Texas, a state known for its agricultural innovation and resilience, the adoption of FRG varieties and increase in organic viticulture could mean a significant change for the Texas wine industry—one that is sustainable, flavorful, and aligned with the increasing global shift towards organic production.
The trends surrounding Fungus-Resistant Grape (FRG) varieties reflect an intersection of sustainability, consumer preferences, and technological advancements. These trends are shaping the future of viticulture and winemaking, positioning FRG varieties as a pivotal innovation in the industry. Here are some key trends:
1. Increased Adoption in Organic Viticulture
FRG varieties are gaining traction among organic vineyards due to their inherent resistance to common fungal diseases, which reduces the need for synthetic chemical treatments.
2. Consumer Awareness and Acceptance
There’s a growing awareness among consumers about the environmental and health impacts of pesticide use in agriculture. As a result, wines produced from FRG varieties are increasingly seen as a healthier and more sustainable option. However, consumer acceptance varies, with a large segment of the market very cautious about genetically modified organisms (GMOs). FRG varieties are mostly being developed through traditional breeding methods rather than genetic engineering making them attractive to organic growers and consumers.
3. Technological Advancements in Breeding
Advances in breeding technologies, including genetic mapping and marker-assisted selection (these are approved organic practices), have significantly improved the quality and disease resistance of FRG varieties. These technological advancements enable the development of new varieties that retain the desired sensory qualities of traditional Vitis vinifera grapes while incorporating disease resistance from other grape species.
4. Regulatory and Policy Shifts
Changes in regulations and policies are influencing the adoption of FRG varieties. Some European regions are recognizing the benefits of these grapes in reducing chemical inputs and are adjusting regulations to support their use. Additionally, there’s a push for clearer labeling practices to inform consumers about the sustainable attributes of wines made from FRG varieties, especially organically produced FRG varieties!
5. Economic and Environmental Sustainability
The economic benefits of adopting FRG varieties are becoming more apparent to growers, including reduced costs associated with disease management and potential for higher yields due to decreased disease pressure.
6. Focus on Quality and Sensory Profiles
Initially, concerns existed about the sensory qualities of wines made from FRG varieties. However, ongoing research and development efforts focus on breeding FRG varieties that produce high-quality wines, comparable to those made from traditional grape varieties. This includes optimizing viticultural practices and winemaking techniques to enhance the sensory profiles of FRG wines.
7. Collaborative Research and Development
There’s a trend towards collaborative efforts among research institutions, breeders, and the wine industry to develop and promote FRG varieties. These collaborations aim to pool resources and knowledge to address the challenges of climate change, disease pressure, and sustainability in viticulture.
In summary, the trends for FRG varieties are driven by a confluence of sustainability concerns, technological innovations, and evolving consumer preferences. These trends highlight the growing importance of FRG varieties in the future of sustainable winemaking and organic viticulture.
As we witness the expansion of organic viticulture in Texas, the future of wine production appears promising. With each vineyard turning to Fungus Resistant Grape varieties, we edge closer to a wine industry that is not only kinder to the planet but also offers wines of exceptional quality and taste. The path forward for Texas and the wine world at large is clear: embracing organic practices and the innovative potential of FRG varieties is not just a trend, but the future of sustainable viticulture.
Source: Pedneault, K., & Provost, C. (2016). Fungus Resistant Grape Varieties as a Suitable Alternative for Organic Wine Production: Benefits, Limits, and Challenges. Scientia Horticulturae, 208, 57-77.
Here is an article from Florida by way of resistant grape varieties from UC-Davis. It follows along the lines of my blog here.
Texas A&M AgriLife Organic 